JP5929996B2 - Road information update system and navigation device - Google Patents

Description

  The present invention relates to a road information update system for updating road data and a navigation apparatus using the same.

  As a prior art, for example, in Patent Document 1, when a vehicle travels on a new road that does not exist in the road map data stored in the storage medium, it is recognized that the road is the new road based on the travel locus of the vehicle. A navigation device having a function (for example, an in-vehicle car navigation device) is described. In this patent document 1, when the certified new road information is transmitted from the navigation device to the information center, the information center updates the road map data based on the received new road information (that is, has a new road learning function). ) Is configured as follows. However, the new road learning function described in Patent Document 1 cannot detect “actually abandoned roads”.

  For this reason, in the new road learning described in Patent Document 1, although a new road is added, for example, when there is a road that has been abolished due to the construction of a new road, the abolished road remains. There is a risk of route guidance using the road.

  Moreover, even if the road map data can be updated as in Patent Document 1, if all the updated road map data is transmitted from the information center to the navigation device, there may be a problem that the data amount becomes excessive. The same applies to road instruction data, and if all such road guidance data (road map data, road instruction data) is transmitted, there is a problem that the data amount becomes excessive.

Japanese Patent No. 3557776

  Therefore, an object of the present invention is to realize a road information update system capable of reducing the amount of data to be transmitted even when road data is updated in an information center, and to realize route guidance according to actual road conditions. The object is to provide a navigation device capable of

The invention of claim 1 includes a storage means for storing the first road map data, a travel locus detecting means for detecting the travel locus of the moving body, and a navigation device comprising a communication means for transmitting information to the outside. And an information center comprising a communication means for communicating information to the navigation device and storing the second road map data, wherein the information center is the first road It has map data, receives the destination information and the departure point information of the mobile body transmitted from the navigation device, and calculates the route R1 from the current location to the destination using the first road map data. Processing and processing for calculating the calculated route R1 guidance information, and calculating the route R2 from the current location to the destination using the second road map data. And the calculated route R2 guide information are compared, the route R1 guide information is compared with the route R2 guide information, and the route R2 exists on the route R2. The guide information cancel information for canceling the guide information not existing in the route R1 and the guide information additional information for adding the guide information that does not exist in the route R1 and exists in the route R2 are transmitted to the navigation device The navigation device is configured to execute a process of calculating a route R1 from the current location to the destination using the first road map data, and a process of calculating guide information of the calculated route R1. The guide information cancellation information and the guide information additional information from the information center are received, and the received guide information cancel information and the guide information are received. Is configured based on the additional information so as to reflect the addition of the cancellation and the guide information of the guidance information with respect to the guide information of the route R1, the guide information cancellation information, displays a map and route in the navigation device It has a feature in that it includes information for preventing old maps and abolished roads from being displayed .

The invention according to claim 2 is mounted on a moving body that travels on a road, and a traveling locus detecting means for detecting a traveling locus of the moving body, a storage means for storing first road map data, and transmitting information to the outside. In the navigation device comprising the communication means, the information on the departure place of the mobile body and the information on the destination are transmitted to the information center, and the destination from the departure place using the first road map data. A process for calculating the route R1 to the ground and a process for calculating the guidance information for the calculated route R1 are executed, and further, a guidance instruction on the route R1 transmitted from the information center is displayed. Guidance information cancellation information for canceling a message and guidance information additional information for adding a guidance instruction message are received, and based on the received guidance information cancellation information and guidance information additional information. It is configured to reflect the addition of the cancellation and the guide information of the guidance information with respect to the guide information of the route R1 Te, the guide information cancellation information, old when displaying a map or route by the navigation device It is characterized in that it contains information for preventing the display of maps and abandoned roads .

Functional block diagram of the road map information update system showing the first embodiment of the present invention Flow chart showing control of navigation device Sequence diagram showing operations of information center and navigation device Functional block diagram explaining information center control Diagram explaining an example of a road change model The figure explaining other examples of a road change model Diagram explaining the control of guessing new and abandoned roads The sequence diagram which shows operation | movement of the information center and navigation apparatus of 2nd Embodiment of this invention. (A) is a figure which shows an example of the guidance information to cancel, (b) is a figure which shows an example of the guidance information to add (A) is a figure which shows the other example of the guidance information to cancel, (b) is a figure which shows the other example of the guidance information to add. Functional block diagram of the model creation device of the third embodiment of the present invention Flow chart showing control of difference group extraction processing unit The figure which shows the aspect in which the newest map data and 1st auxiliary map data change The figure which shows the aspect which determines dependency The figure which shows the aspect in which the newest map data and 2nd auxiliary map data change 14 equivalent diagram Diagram showing the structure of the road change model Flow chart showing control of model extraction processing unit Figure showing examples of road change patterns FIG. 2 equivalent view showing a fourth embodiment of the present invention

(First embodiment)
Hereinafter, a first embodiment of the present invention will be described with reference to FIGS. First, FIG. 1 is a functional block diagram schematically showing the configuration of the road information update system of the present embodiment. This system includes, for example, an in-vehicle navigation device 1 and an information center 21 as navigation devices. In addition, although the navigation apparatus 1 is provided in the some vehicle (moving body), FIG. 1 has illustrated one of them. The information center 21 is provided as a facility fixed at a predetermined position on the ground.

  As shown in FIG. 1, the navigation device 1 includes a position detection unit 2, a map data storage unit 3, a switch information input unit 4, a memory unit 5, a display unit 6, a voice output unit 7, a data communication unit 8, and a control unit 9. It has. Hereinafter, these configurations will be described in order.

  The position detection unit 2 includes a GPS sensor, a gyro sensor, a vehicle speed sensor, and the like, and has a function of detecting the current position (current position) of the vehicle. In addition, as long as the current position of the vehicle can be detected, it is not necessary to provide all the sensors, and it is sufficient to provide at least one of them. However, since the position of the vehicle can be accurately detected when the GPS sensor is provided, in the following description, the position detection unit 2 is assumed to include at least the GPS sensor.

  The map data storage unit (storage means) 3 is composed of, for example, a DVD player, a hard disk, a CD player, etc., and stores road map data (first road map data) including road map information. The road map data stored in the map data storage unit 3 stores a predetermined road number in association with each road, and depending on the road, a predetermined road number may be stored for each section of the road. It is stored in association.

  The switch information input unit 4 is a switch attached to the left and right or top and bottom of the display device as the display unit 6. The driver can make various selections, instruct various operations, and set a destination via the switch information input unit 4. The memory unit 5 is composed of, for example, a ROM or a RAM. The ROM stores programs for executing various processes described later, including a navigation program. The RAM of the memory unit 5 is formed with an area for temporarily storing road map data and the like acquired from the work memory of the program and the map data storage unit 3.

  The display unit 6 is configured as a display device for displaying a map for navigating the driver and displaying a destination selection screen and the like. The voice output unit 7 utters voices for navigating the driver and explanations of screen operations. The data communication unit 8 has a mutual communication function, and is composed of, for example, a mobile phone or a car phone.

  The control unit 9 controls the above-described units of the navigation device 1, and includes a map data acquisition unit 10, a map matching unit 11, a route calculation unit 12, a route guide unit 13, a drawing unit 14, a screen control management unit 15, and communication control. A unit 16 and a travel locus creating unit 17 are provided. The operation of each part will be described.

  First, the map data acquisition part 10 acquires the map data required by each said part of the control part 9 from the map data storage part 3 as mentioned later, and provides each part. The processing in the map data acquisition unit 10 and the processing in other units are executed using the ROM and RAM of the memory unit 5.

  Further, the map matching unit 11 uses the current position of the vehicle detected by the position detection unit 2 and the road shape data of the map data acquired from the map data storage unit 3 on which road the current position exists. Is identified. At this time, the map data acquisition unit 10 acquires necessary map data from the map data storage unit 3.

  In the route calculation unit 12, the current position calculated by the map matching unit 11 or the departure point designated by the driver reaches the destination set by the driver by displaying a desired map using the switch information input unit 4. Calculate the route. The route guidance unit 13 calculates points necessary for guidance from the result of the route calculation and road shape data stored in the road map data, intersection position information, crossing position information, etc. It is calculated whether an appropriate guidance (such as an instruction to turn right or left, ie, so-called navigation) is necessary. When the vehicle travels on the calculated and set route, the route guidance is executed by the route guidance unit 13 based on the calculated guidance. The drawing unit 14 draws a map of the current position, a schematic diagram of the expressway, an enlarged view of the vicinity of the intersection in the vicinity of the intersection, and the like according to instructions from the screen control management unit 15 and displays them on the display unit 6.

  A travel locus creation unit (running locus detection means) 17 creates a travel locus of the host vehicle based on the position data from the position detection unit 2. As will be described in detail later, when a predetermined condition is satisfied, the travel locus information, that is, new road information is stored in the memory unit 5.

  The communication control unit 16 instructs the data communication unit 8 when it is instructed by the driver using the switch information input unit 4 and every time a predetermined time elapses so that mutual communication with the information center 21 is possible. To do. Even when the data communication unit 8 receives a request from the information center 21, the communication control unit 16 makes the above-described mutual communication possible. Thus, when mutual communication becomes possible, the travel locus information (new road information) stored in the memory unit 5 is uploaded to the information center 21. Further, when an information distribution request is made to the information center 21 or when there is an information transmission request from the information center 21 to the communication control unit 16, the information center 21 distributes (transmits) the information center 21 in response to the request. Information is received and stored in the memory unit 5. Information distributed from the information center 21 includes application programs, map data, route guidance instruction information described later, and the like. The data communication unit 8 and the communication control unit 16 constitute communication means.

  On the other hand, the information center 21 is connected to a radio base station 18 capable of communicating with each vehicle through a telephone station 19, and data is transmitted and received between the radio base station 18 and the navigation device 1. The information center 21 includes a line terminal device (communication means) 22 that performs communication via the telephone station 19, a server 23 that processes necessary information, and a database 24 that stores necessary data. In the information center 21, data such as travel locus information (new road information) obtained from the vehicle navigation device 1 by communication is stored in the database 24. Then, in the information center 21, the server 23 is based on the travel locus information (new road information), the current location and destination information of the vehicle obtained from the vehicle navigation device 1 by communication, and the road map data in the database 24. The data processing (for example, new and old road estimation processing (first embodiment), route calculation processing, route guidance comparison processing (second embodiment), etc., which will be described later) is executed, and the data processing result is stored in the database 24. In the second embodiment, the information center 21 adds a function of transmitting the information of the route guidance comparison result using the line terminal device 22 to the navigation device 1 that has transmitted the current location and destination information. Yes.

Next, various data processing executed in the navigation device 1 and the information center 21 configured as described above will be described with reference to FIGS.
First, FIG. 2 is a flowchart illustrating a process executed by the control unit 9 of the navigation apparatus 1 and storing the travel locus and transmitting the information to the information center 21 when a predetermined condition is satisfied. The travel locus creation unit 17 takes in the current position coordinates (latitude and longitude values) detected by the position detection unit 2 every predetermined time (for example, 1 to 5 seconds), and creates travel locus information (S101). The traveling direction can be determined from the traveling locus. Further, since the travel distance and the time required for the travel can be obtained, the average travel speed can also be known.

  Next, the travel trajectory obtained in this way is compared with the road shape data of the road map data acquired from the map data storage unit 3, and it is determined whether or not the vehicle is in a road leaving state (S102). If it is a road leaving state (S102: YES), it is determined whether or not there is a similar traveling locus as compared with the information of the traveling locus already accumulated (S103). If there is no similar traveling locus (S103: NO), the number of creation is set to 1 (S104), information including the traveling locus is stored in the memory unit 5 (S105), and this processing is terminated. . That is, information such as a travel locus (hereinafter referred to as travel locus information) is stored as a newly created road that does not exist in the road map data. The travel locus information is information including, for example, a travel locus, a storage time interval of position coordinates constituting the travel locus, the number of times the travel locus is created, and the like. In this case, the control unit 9 has a function as travel locus information collecting means.

  When determining whether or not the road is in the state of leaving the road in S102, the map matching process in the map matching unit 11 is used, and the degree of coincidence (approximation) between the travel trajectory and road shape data that falls within a predetermined range where map matching is possible. When the degree) is low (or not), it may be determined that the road is leaving. For example, it is preferable not to include a detour route temporarily provided during road construction in the new road here. Such a detour has a short road distance, is provided in parallel with the road before the construction, and the distance from the road before the construction is also short. Based on the characteristics of such a detour, the travel locus is not adopted as the travel locus of the new road to be accumulated.

  In S105, when information including a travel locus is stored in the memory unit 5, not only a new road (a road leaving portion) that does not exist on the map but also a road before and after the new road are included as the travel locus. A road, that is, a road before and after the new road is added to the new road (set) and stored.

  On the other hand, if there is a similar traveling locus (S103: YES), it is determined whether or not the number of times the traveling locus is created is greater than or equal to a predetermined value (S106). : NO), the number of times of creation for the travel locus is increased by 1 (S107), and this process is terminated.

  In this way, when the same travel locus is created and the number of creations increases, and the number of creations of the travel locus exceeds a predetermined value (S106: YES), it is stored in S105. The travel locus information, that is, the new road information is transmitted to the information center 21 (S108). Thereafter, the information such as the transmitted travel locus is cleared from the memory unit 5 (S109), and this process is terminated. In S109, information such as the transmitted travel locus is cleared from the memory unit 5, but instead, information indicating that the transmitted travel locus or the like has been transmitted is recorded in the memory unit 5. You may comprise as follows. With this configuration, it can be seen that the road corresponding to the transmitted travel locus has been transmitted. Thereafter, when traveling on the same road, the above-described processing (determining as a new road or new road information It is possible to prevent the processing or the like transmitted to the information center 21 from being executed.

  Here, the reason why the travel trajectory information (new road information) that traveled on a new road for the first time when the number of travel trajectory creations exceeds a predetermined value is transmitted to the information center 21 is as follows. That is, there is a possibility that a traveling locus that does not match the actual shape / position of the new road may be detected due to problems such as accuracy in detecting the traveling locus. On the other hand, when the same traveling locus is detected a plurality of times, it can be said that the locus is highly likely to coincide with the actual shape and position of the new road. The predetermined value may be set to a numerical value of 1 or more, but is preferably a numerical value that is not very large (for example, 3 or 5). The reason for this setting is that when the vehicle travels on a new road, it is preferable to transmit the new road information as soon as possible, that is, the travel locus information traveled on the new road, to the information center 21.

  Next, FIG. 3 thru | or about the process which the information center 21 performs, and the process which the navigation apparatus 1 each mounted in the vehicle of 1 or more (this example demonstrates and takes 1 example) are shown. This will be described with reference to FIG. First, FIG. 3 is a sequence diagram for explaining the operation (processing) of the information center 21 and the operation (processing) of the navigation device 1 mounted on one vehicle A.

  As shown in step S201 in FIG. 3, the information center 21 executes a process for creating a road change model in advance (function as a model creating unit). In the process of creating this road change model, as shown in FIG. 4, the old road map data used in the past (hereinafter referred to as old road map data) and the latest updated road map data (hereinafter referred to as new road map data). Compared with the second road map data (referred to as road map data), a large number of road changes where there are abandoned roads and new roads that are currently in use are extracted and based on the abandoned roads and new roads Then, many types of road change models are created and stored in the database 24. When creating a road change model, the new road map data to be compared is preferably the latest road map data that has been updated recently, but is not limited to this, and roads that have been updated more recently than the old road map data to be compared. It may be map data.

  The information center 21 is provided with a plurality of road map data. The plurality of road map data includes an old version (multiple generations) of road map data in time series and a new version of road map currently in use. With map data. Further, the information center 21 is configured so that the entire road map data is periodically updated. This road map data update processing is information on abolished roads given from outside (a road map data production company, a government office managing roads, etc.) or obtained inside the information center 21 as described later. And it is performed based on the information of the newly created road.

  Here, an example of a road change model is shown in FIG. It is assumed that a certain intersection in the old road map data is a cross road as shown in FIG. It is assumed that this intersection is changed to a rotary intersection (or roundabout) as shown in FIG. 5B in the new road map data. The road change model at this intersection is a model as shown in FIG. In this road change model, a rotary road drawn with a solid line indicates a new road, and a crossroad drawn with a broken line indicates a discontinued road.

  As the road change model, not only new roads and abandoned roads are memorized, but also new roads and roads around the new roads (that is, roads before and after new roads), abandoned roads and The roads before and after that are stored as a set. If the preceding and following roads are stored as a set as described above, the determination accuracy of the process of comparing and determining (collating) a travel locus pattern and a road change model pattern, which will be described later, can be increased.

  FIG. 6 shows another example of a road change model. In the old road map data, it is assumed that an intersection with an expressway is a loop-shaped branch road 27 having a small radius of curvature, as shown in FIG. It is assumed that this intersection is changed to an arc-shaped branch 28 having a large curvature radius as shown in FIG. 6B in the new road map data. The road change model of this intersection is a model as shown in FIG. In this road change model, the branch road 28 drawn with a solid line indicates a new road, and the branch road 27 drawn with a broken line indicates a discontinued road. In the case of the road change model shown in FIG. 6, the new road and the roads before and after the road, the abandoned road and the roads before and after the road are set and stored.

  In the present embodiment, the above two examples are shown as the road change model, but actually, various types of road change models are created and stored in the database 24. In the case of other road change models, the new road and the roads before and after the new road and the abandoned road and the roads before and after the road are stored as a set.

  Next, in the navigation device 1 of the vehicle A, when the number of times of creation of the travel locus that has traveled on the new road exceeds a predetermined value, the control shown in step S202 in FIG. New road information) is transmitted to the information center 21.

  Subsequently, when the travel center information (new road information) traveled on the new road from the navigation device 1 of the vehicle A is received at the information center 21, as shown in step S203 of FIG. (Function as means) is executed. Specifically, a process of comparing the received travel locus information with various road change models in the database 24 is executed, and a road change model corresponding to the received travel locus is selected. For example, if the received travel locus is a travel locus having a shape as shown in FIG. 7A, a model having a shape as shown in FIG. 7B is selected as the road change model. Then, in the information center 21, based on the received travel locus (see FIG. 7A) and the road change model (FIG. 7B), a new road 29 indicated by a solid line in FIG. The abandoned road 30 indicated by the broken line in FIG. 7C is estimated, and the estimated information (information on the new road 29 and information on the abandoned road 30) is stored in the database 24.

  The information center 21 is also configured to receive travel locus information (new road information) traveled on a new road transmitted from the navigation device 1 of other vehicles (not shown) at any time. When the information center 21 receives the travel locus information from the navigation devices 1 of other vehicles, as described above, the information center 21 selects the road change model corresponding to the received travel locus, And the information on the estimated new road and abandoned road is stored in the database 24.

  In the information center 21, the new road and the abandoned road estimated as described above are reflected in the update process of the road map data stored in the information center 21. At this time, all of the road map data may be updated, but it is better to update only the updated portion of the latest road map data that has been updated recently.

  As described above, in the present embodiment, the new road and the abandoned road are estimated using the road change model, so that it is possible to estimate the road in accordance with the actual road condition. In addition, since the road change model is used, road updating can be performed in a system that is less expensive than the conventional system. In the information center 21, in order to obtain the latest road information (new roads / obsolete roads) from a plurality of vehicles, periodic updates given from outside (a road map data production company, a government office managing roads, etc.) are made. The latest road map data can be stored (or updated) without waiting.

(Second Embodiment)
8 to 10 show a second embodiment of the present invention. In addition, the same code | symbol and the same step number are attached | subjected to the same structure and 1st step as 1st Embodiment. In the second embodiment, a process executed by the information center 21 and a process executed by the navigation device 1 mounted on each vehicle (in the present embodiment, two units will be described as an example) will be described.

  First, as shown in step S201 in FIG. 8, the information center 21 executes a process for creating a road change model in advance (function as a model creation unit) in the same manner as in the first embodiment.

  Next, in the navigation device 1 of the vehicle A, when the number of times of creation of the travel locus that has traveled on the new road exceeds a predetermined value, the control shown in step S202 of FIG. The travel locus information (new road information) traveled on the road is transmitted to the information center 21.

  Subsequently, when the information center 21 receives the travel locus information (new road information) traveled on the new road from the navigation device 1 of the vehicle A, as shown in step S203 of FIG. 8, the same as in the first embodiment. Thus, the new and old road estimation processing (function as estimation means) is executed. As a result, the information center 21 estimates the new road and the abandoned road, and stores the estimated information (new road information and abandoned road information) in the database 24. Then, in the same manner as in the first embodiment, when the information center 21 receives the travel locus information from the navigation devices 1 of a plurality of other vehicles, the information center 21 selects a road change model corresponding to the received travel locus, The abandoned road is estimated, and the information on the estimated new road and abandoned road is stored in the database 24.

  Thereafter, as shown in step S204 of FIG. 8, when the destination is set in order to execute the route calculation process and the route guidance process in the navigation device 1 of the vehicle B, the destination of the set destination is set. Information and information on the current location of the vehicle B (which may be the departure location) are transmitted to the information center 21 (step S205). Further, in the navigation device 1 of the vehicle B, following the transmission process, as shown in step S206, the current location is obtained using the road map data (first road map data) mounted in the navigation device 1. From the process of calculating the route R1 to the destination, the road shape data stored in the calculated route R1 and road map data, the position information of the intersection, the position information of the crossing, etc. A process (calculation process of guidance information) for calculating necessary points and calculating what guidance instructions (instructions for turning right or left, etc., that is, so-called navigation) are necessary.

  Next, when the information center 21 receives the destination information and the information on the current location of the vehicle B (which may be the departure location) transmitted from the navigation device 1 of the vehicle B, as shown in step S207, The route from the current location to the destination using the road map data stored in the database 24 (this is the same road map data installed in the navigation device 1 of the vehicle B, the first road map data) From the calculated R1 and the calculated route R1 and road shape data stored in the road map data, intersection position information, crossing position information, etc., points necessary for the guidance instruction are calculated. Then, a process for calculating what kind of guidance instruction is necessary (a process for calculating guidance information) is performed.

  Subsequently, as shown in step S208, the information center 21 stores road map data stored in the database 24 (this is the same as the road map data mounted in the navigation device 1 of the vehicle B). , The first road map data) and the second road map data (the first road map data inferred) reflecting the information of the estimated new road and the abolished road stored in the database 24 A process for calculating a route R2 from the current location to the destination from road map data reflecting information on new roads and abolition roads, and roads stored in the calculated route R2 and the second road map data To calculate the points necessary for guidance instructions and what kind of guidance instructions are necessary from the shape data of the car, the position information of the intersection, the position information of the crossing, etc. The calculation of the guidance information processing) and is carried out. In this case, the calculated route R2 is basically the same route as the calculated route R1, and the difference is that when the estimated abandoned road is included in the route R1, the estimated route R2 is estimated. It is a point that becomes a route via a new road. The road map data used when calculating the route R2 is road map data reflecting the estimated new road and the abolished road with respect to the first road map data as second road map data. However, it may be road map data updated after the first road map data.

  Next, as shown in step S209, the information center 21 compares the guidance information on the route R1 and the guidance information on the route R2, and executes a process of extracting the difference between the two (route guidance comparison processing). Then, as shown in step S210, the information center 21 transmits, to the navigation device 1 of the vehicle B, guidance information cancellation information for canceling the guidance information that exists on the route R1 and does not exist on the route R2. This guidance information cancellation information includes information for canceling the guidance instruction.

  Furthermore, as shown in step S211, the information center 21 provides guidance information additional information for adding the guidance information that does not exist on the route R1 and exists on the route R2, to the navigation device 1 of the vehicle B. Send. As this guidance information additional information, guidance information on a new road is transmitted to the navigation device 1 of the vehicle B.

  On the other hand, when the navigation apparatus 1 of the vehicle B receives the guidance information cancellation information from the information center 21, as shown in step S212, the navigation information 1 is converted into the guidance information on the route R1 based on the received guidance information cancellation information. On the other hand, a process of reflecting the cancellation of the guidance information, that is, canceling the corresponding guidance instruction is performed.

  At the same time, when the navigation apparatus 1 of the vehicle B receives the guidance information additional information from the information center 21, as shown in step S213, the navigation apparatus 1 of the vehicle B responds to the guidance information on the route R1 based on the received guidance information additional information. A process of reflecting the addition of the guidance information, that is, adding a corresponding guidance instruction or displaying a guidance map for easily displaying a new map and a new road is performed. As a result, the navigation apparatus 1 of the vehicle B can execute route guidance using the same guidance information as the guidance information of the route R2 calculated by the information center 21, that is, the route passing through the new road.

  In the present embodiment having such a configuration, in the navigation device 1 of the vehicle A, a travel locus that travels on a new road that is not included in the road map data is stored in a memory unit, and the travel of the new road is performed when a predetermined condition is satisfied. The track information is transmitted to the information center 21. Then, the information center 21 receives the traveling track information of the new road from the navigation device 1 of the vehicle A, and compares the received traveling track information of the new road with the road change model stored in the database 24. Configured to guess new roads and abandoned roads. Since it comprised in this way, according to this embodiment, the information center 21 can estimate correctly the new road which is not in road map data, and the abolished abandoned road.

  In the present embodiment, the information center 21 receives the destination information and the current location (departure point) information transmitted from the navigation device 1 of the vehicle B, and is stored in the database 24. A process of calculating a route R1 from the current location (departure point) to the destination using map data (the same as the road map data mounted in the navigation device 1 of the vehicle B), and the calculated route R1 From the road shape data stored in the road map data, intersection position information, crossing position information, etc., calculate the points necessary for guidance instructions and what kind of guidance instructions are necessary. Processing (guidance information calculation processing) was executed. Further, in the information center 21, the road map data (the same as the road map data mounted in the navigation device 1 of the vehicle B) and information on the estimated new road and abandoned road stored in the database 24 are used. Is used to calculate the route R2 from the current location (departure point) to the destination, road shape data stored in the calculated route R2 and road map data, intersection position information, level crossing From the position information and the like, a process for calculating points necessary for the guidance instruction and calculating what guidance instruction is necessary (guidance information calculation process) is performed. In this case, the calculated route R2 is a route that passes through the estimated new road when the estimated new road is included in the route R2. In addition, the information center 21 compares the guidance information on the route R1 and the guidance information on the route R2, and executes a process of extracting the difference between them (route guidance comparison processing). The navigation information 1 for the vehicle B includes the guidance information cancellation information for canceling the guidance information that does not exist, and the guidance information additional information that is guidance information that does not exist on the route R1 and adds the guidance information that exists on the route R2. Send. Further, when the navigation apparatus 1 of the vehicle B receives the guidance information cancellation information and the guidance information additional information from the information center 21, the navigation apparatus 1 generates a guidance instruction for the route R1 based on the received guidance information cancellation information and the guidance information additional information. On the other hand, the cancellation of the guidance instruction and the addition of the guidance instruction are reflected. As a result, the navigation device 1 of the vehicle B can execute route guidance using the same guidance information as the route R2 guidance information calculated by the information center 21, that is, a route that passes through a new road that is not in the road map data. .

  In the second embodiment, the guidance instruction on the route is exemplified as the guidance information. However, the present invention is not limited to this, and road map data may be used. Moreover, both a guidance instruction on the route and road map data may be used.

  Specifically, when both the guidance instruction on the route and the road map data are transmitted from the information center 21 to the navigation device 1 as the guidance information, first in step S211 of FIG. Information that cancels the instruction and information on a map area that prohibits map display and route display are included. This prohibited map area information is information for masking the old map and the abandoned road so as not to be displayed when a map, a route, or the like is displayed on the display of the navigation device 1.

  Next, as shown in step S211, the information center 21 provides guidance information additional information for adding the guidance information that does not exist on the route R1 and exists on the route R2, to the navigation device 1 of the vehicle B. Send to. This guidance information additional information includes guidance information on a new road, information on a new map and a guidance map (e.g., road data such as pictures and images) that easily displays the new road. As the information of the guide map, image data, code information (information specifying the image data when the image data is stored on the navigation device 1 side), or the like may be transmitted.

  With this information, when the navigation apparatus 1 of the vehicle B receives the guidance information cancellation information from the information center 21, as shown in step S212, the navigation apparatus 1 of the vehicle B responds to the guidance information on the route R1 based on the received guidance information cancellation information. The process of reflecting the cancellation of the guidance information, that is, canceling the corresponding guidance instruction or masking the old map and the abandoned road so as not to be displayed is performed.

  At the same time, when the navigation apparatus 1 of the vehicle B receives the guidance information additional information from the information center 21, as shown in step S213, the navigation apparatus 1 of the vehicle B responds to the guidance information on the route R1 based on the received guidance information additional information. A process of reflecting the addition of the guidance information, that is, adding a corresponding guidance instruction or displaying a guidance map for easily displaying a new map and a new road is performed. As a result, the navigation apparatus 1 of the vehicle B can execute route guidance using the same guidance information as the guidance information of the route R2 calculated by the information center 21, that is, the route passing through the new road. Note that only by masking the old road, a new map and a guide map for easily displaying the new road need not be transmitted and displayed.

  Here, FIG. 9 shows an example of cancellation and addition when the guidance information includes both a guidance instruction on the route and road map data. In this case, the guidance information on the abandoned road as shown in FIG. 9A is canceled. Specifically, the message “This is the left direction” is canceled, and the road that turns left (the abandoned road) and The display of the surrounding map is prohibited (masked). Then, new road guidance information as shown in FIG. 9B is added. Specifically, a message “This is the right direction” is added, and a road that turns right and turns around (new road) ) And the surrounding map guide map are displayed. In this case, it may be configured such that the information of the message “This is the right direction ahead” is included in the image information of the guide map.

  FIG. 10 shows another example of canceling and adding guidance information. In this case, the guidance information on the abandoned road as shown in FIG. 10A is canceled. Specifically, the message “This is the right direction” is canceled, and the loop-shaped branch 27 (discontinued) (Road) and surrounding maps are prohibited (masked). Then, new road guidance information as shown in FIG. 10B is added. Specifically, a message “This is the right direction” is added, and an arc-shaped branch road with a large curvature radius is added. A guide map of 28 (new road) and its surrounding map is displayed. In the case of FIG. 10, the content of the guidance instruction message is the same, but the point in time when the message is output, that is, the point of the guidance instruction is different. In addition, you may comprise so that the information of the message "It is a right direction from now on" may be included in the image information of the said guide map.

  In the second embodiment, the road information update process using the road change model of the first embodiment is premised. However, the road information update process is not limited to this, and a conventionally known road Information update processing (processing for updating part or all of the road map data) may be used.

(Third embodiment)
11 to 19 show a third embodiment of the present invention. In addition, the same code | symbol and the same step number are attached | subjected to the same structure and the same step as 1st Embodiment and 2nd Embodiment. In the third embodiment, an example of a model creation device 31 that creates many types of road change models used in the first embodiment and the second embodiment is shown. The model creation device 31 according to the present embodiment includes, for example, a server 23 and a database 24 of the information center 21.

  As shown in FIG. 11, the model creation device 31 includes a difference group extraction processing unit (difference group creation unit) 32, a map database group 33, a difference group database (difference group storage unit) 34, and a map update information input unit. 35, a model extraction processing unit (model extraction means) 36, and a road change model database (model storage means) 37. In this case, the difference group extraction processing unit 32, the map update information input unit 35, and the model extraction processing unit 36 are configured by the server 23 of the information center 21. The map database group 33, the difference group database 34, and the road change model database 36 are configured by the database 24 of the information center 21.

  The difference group extraction processing unit 32 has a function of performing a minimum grouping process that guarantees a road network against changes in the road. The road change is, for example, a change such as addition / change / deletion of a road. The map database group 33 includes a latest map database 38, a first auxiliary map database 39, and a second auxiliary map database 40. The difference group database 34 stores a large number of difference groups extracted by the difference group extraction processing unit 32. The road change model database 36 stores various (many) road change models extracted (or corrected) by the model extraction processing unit 35.

  The map update information input unit 35 inputs map update information for instructing addition or deletion of a link to map data from the outside. In this case, according to the road being opened or closed, for example, an operator (operator) operates an input device (for example, a keyboard, a mouse, etc.) (not shown) so that the map update information becomes the map update information. Input to the input unit 35.

  The latest map database 38 stores the latest map data indicating the connection mode between nodes and links. The node indicates an intersection (branch point) on the road, and the link indicates a road (including a direction in which the vehicle is allowed to travel) between the nodes. When the map update information instructing addition of a link is input to the map update information input unit 35 in response to the road opening, the difference group extraction processing unit 32 stores the addition of the link in the latest map database 38. When the map update information that reflects the updated map data is input to the map update information input unit 35 in response to the fact that the road is closed, the deletion of the link is updated. The latest map data stored in the database 38 is reflected. That is, the latest map data stored in the latest map database 38 is updated regardless of whether a map update instructing addition of a link or a map update instructing deletion of a link occurs.

  In the initial state (the state where map data is registered in the first auxiliary map database 39), the first auxiliary map database 39 uses the same map data as the latest map data stored in the latest map database 38 as the first auxiliary map data. Remember. When the map update information instructing deletion of the link is input to the map update information input unit 35, the difference group extraction processing unit 32 stores the deletion of the link in the first auxiliary map database 39. Reflected in the data, even if the map update information instructing the addition of the link is input to the map update information input unit 35, the addition of the link is added to the first auxiliary map data stored in the first auxiliary map database 39. Does not reflect. That is, the first auxiliary map data stored in the first auxiliary map database 39 is updated only when a map update instructing deletion of a link occurs, and a map update instructing addition of a link occurs. Will not be updated.

  The second auxiliary map database 40 uses the same map data as the latest map data stored in the latest map database 38 as the second auxiliary map data in the initial state (a state in which the map data is registered in the second auxiliary map database 40). Remember. When the map update information instructing addition of a link is input to the map update information input unit 35, the difference group extraction processing unit 32 stores the link addition in the second auxiliary map database 40. Reflected in the data, even if the map update information instructing the deletion of the link is input to the map update information input unit 35, the deletion of the link is added to the second auxiliary map data stored in the second auxiliary map database 40. Does not reflect. That is, the second auxiliary map data stored in the second auxiliary map database 40 is updated only when a map update instructing addition of a link occurs, and a map update instructing deletion of a link occurs. Will not be updated.

  As described above, the first auxiliary map data stored in the first auxiliary map database 39 and the second auxiliary map data stored in the second auxiliary map database 40 have the opposite characteristics. The first auxiliary map data is updated only when a map update instructing deletion of the link, that is, a map update in which the route through which the vehicle can pass is reduced, so only the map update that is disadvantageous for the user is performed. On the other hand, the second auxiliary map data is updated only when a map update instructing addition of a link, that is, a map update in which the route through which the vehicle can pass increases, is updated. It is a map reflecting the map update that is advantageous to the user.

  Next, difference group extraction processing executed by the difference group extraction processing unit 32 will be described with reference to FIGS. First, in step S301 of the flowchart of FIG. 2, the difference group extraction processing unit 32 determines whether map update information has been input to the map update information input unit 35, and determines whether map update has occurred. The difference group extraction processing unit 32 determines that map update information has been input to the map update information input unit 35, for example, when an operator operates an input device, and determines that map update has occurred (" YES ”), the contents of the map update are reflected in the latest map data stored in the latest map database 38 (step S302). That is, the difference group extraction processing unit 32 reflects the addition of the link to the latest map data and the update of the map instructing the deletion of the link if the update of the map of instructing the addition of the link occurs. If there is, link deletion is reflected in the latest map data.

  Next, the difference group extraction processing unit 32 determines whether the map update is a map update instructing addition of a link or a map update instructing deletion of a link (steps S303 and S304). When the difference group extraction processing unit 32 determines that the update is a map update instructing deletion of the link (“YES” in step S303), the first auxiliary map stored in the first auxiliary map database 39 stores the deletion of the link. This is reflected in the data (step S305). In this case, the difference group extraction processing unit 32 does not reflect the deletion of the link in the second auxiliary map data stored in the second auxiliary map database 40.

  On the other hand, when the difference group extraction processing unit 32 determines that the update is a map update instructing addition of a link (“YES” in step S304), the addition of the link is stored in the second auxiliary map database 40. Reflected in the auxiliary map data (step S306). In this case, the difference group extraction processing unit 32 does not reflect the addition of the link on the first auxiliary map data stored in the first auxiliary map database 39.

  After reflecting the deletion of the link in the first auxiliary map data, the difference group extraction processing unit 32 stores the route search between the nodes located at both ends of the deleted link in the first auxiliary map database 39 at that time. Whether or not the route search on the first auxiliary map data has succeeded (between nodes), on the first auxiliary map data, that is, the first auxiliary map data reflecting the deletion of the link (step S307). It is determined whether or not it is possible to pass (step S308). If the difference group extraction processing unit 32 determines that the route search on the first auxiliary map data is successful (“YES” in step S308), the series of processing ends.

  On the other hand, if the difference group extraction processing unit 32 determines that the route search on the first auxiliary map data has failed ("NO" in step S308), the route search between the nodes located at both ends of the deleted link. Is performed on the latest map data stored in the latest map database 38 at that time (step S309), and it is determined whether or not the route search on the latest map data is successful (step S310).

  If the difference group extraction processing unit 32 determines that the route search on the latest map data has been successful ("YES" in step S310), the contents of the map update that has occurred from the initial latest map data to the current latest map data. The map update contents determined to have a dependency relationship are grouped as map difference data (step S311), and the series of processing ends.

  When the difference group extraction processing unit 32 determines that the route search on the latest map data has failed ("NO" in step S310), the second auxiliary map data is copied to temporarily store the second auxiliary map data. The target link is deleted from the temporary second auxiliary map data (step S312), and a route search between nodes located at both ends of the target link is performed on the temporary second auxiliary map data. (Step S313), it is determined whether or not the route search on the temporary second auxiliary map data has succeeded (Step S314).

  If the difference group extraction processing unit 32 determines that the route search on the temporary second auxiliary map data has succeeded ("YES" in step S314), the update link included in the route successfully searched and the target It is determined that there is a dependency relationship with the link, the map update content determined to have the dependency relationship is grouped as map difference data, and the update link included in the route that has been successfully searched for the route is temporarily a second auxiliary map The data is deleted from the data (step S315), and the above steps S313 and S314 are repeated. When the difference group extraction processing unit 32 determines that the route search on the temporary second auxiliary map data has failed ("NO" in step S314), the series of processing ends.

The above process will be described with reference to FIGS. 13 to 16 by giving specific examples. here,
(1) When a map update instructing the addition of the first link occurs, and then a map update instructing the deletion of the second link occurs (2) A map update instructing the deletion of the first link occurs, Then, the case where the map update which instruct | indicates deletion of a 2nd link generate | occur | produces is demonstrated sequentially.

First, (1) a case where a map update instructing addition of the first link occurs, and then a map update instructing deletion of the second link occurs will be described.
In this case, as shown in FIG. 13, in the initial latest map data stored in the latest map database 38, nodes “A” to “F” and links “a1”, “a2” to “g1”, and “g2” A case where the connection mode is as shown in the figure will be described. The initial first auxiliary map data stored in the first auxiliary map database 39 is the same as the initial latest map data. When a map update instructing addition of links “h1” and “h2” (corresponding to the first link) connecting the node “C” and the node “F” occurs in this state, the difference group extraction processing unit 32 The first latest map data (corresponding to the next latest map data) is created by reflecting the addition of the links “h1” and “h2” in the initial latest map data, but the addition of the links “h1” and “h2” Is not reflected in the initial first auxiliary map data, the initial first auxiliary map data is left as it is, and the initial first auxiliary map data is set as the first first auxiliary map data (corresponding to the next first auxiliary map data). .

  When a map update instructing deletion of the link “e1” (corresponding to the second link) connecting the node “A” and the node “E” further occurs from this state, the difference group extraction processing unit 32 causes the link “ The second period latest map data (corresponding to the next period latest map data) is created by reflecting the deletion of “e1” in the first period latest map data, and the deletion of the link “e1” is the first period first auxiliary map data The second period first auxiliary map data (corresponding to the next period first auxiliary map data) is created in reflection.

  Here, the difference group extraction processing unit 32, as shown in FIG. 14, from the node “A” (corresponding to the first node) located at both ends of the deleted link “e1” to the node “E” (to the second node). Route search to the second phase first auxiliary map data, but the second phase first auxiliary map data does not reflect the addition of the links “h1” and “h2” as described above. , The route search from the node “A” to the node “E” fails. Next, when the route search on the second period first auxiliary map data fails, the difference group extraction processing unit 32 routes the node “A” located at both ends of the deleted link “e1” to the node “E”. The search is performed on the second period latest map data. However, since the second period latest map data reflects the addition of the links “h1” and “h2” as described above, the links “h1” or “h2” are reflected. The route search from the node “A” including “to the node“ E ”is successful. Specifically, the route search through the links “a1”, “b1”, “h1”, “g1” (“f2” may be used) is successful.

  Then, when the difference group extraction processing unit 32 succeeds in the route search on the second period latest map data in this way, the contents of the map update generated from the initial latest map data to the current latest map data, that is, It is determined that there is a dependency between the addition of the links “h1” and “h2” and the deletion of the link “e1”, and the addition of the links “h1” and “h2” determined to have the dependency and the link “e1” ”Is grouped as map difference data and stored in the difference group database 34.

  Here, in the present embodiment, when road changes (updates) are grouped and stored as map difference data as described above, information on the changed road purpose (road purpose) is added. Specific examples of road purpose information include freeway main line to main line transfer (see Fig. 17), left and right turn on general roads (example of change pattern in which a simple intersection is changed to a roundabout, etc.) Yes, these pieces of information are added in association with the grouped map difference data.

Next, (2) a case where a map update instructing the deletion of the first link has occurred and then a map update instructing the deletion of the second link has occurred will be described.
In this case, as shown in FIG. 15, in the initial latest map data stored in the latest map database 38, nodes “G” to “L” and links “i1”, “i2” to “n1”, “n2” A case where the connection mode is as shown in the figure will be described. The initial first auxiliary map data stored in the second auxiliary map database 11 is the same as the initial latest map data. When a map update instructing deletion of the links “l1” and “l2” (corresponding to the first link) connecting the node “I” and the node “K” occurs from this state, the difference group extraction processing unit 32 The first latest map data (corresponding to the next latest map data) is created by reflecting the deletion of the links “l1” and “l2” in the initial latest map data, but the links “l1” and “l2” are deleted. Is not reflected in the initial second auxiliary map data, the initial second auxiliary map data is left as it is, and the initial second auxiliary map data is set as the first second auxiliary map data (corresponding to the next second auxiliary map data). .

  When a map update instructing deletion of the links “n1” and “n2” (corresponding to the second link) connecting the node “H” and the node “L” further occurs from this state, the difference group extraction processing unit 32 , The deletion of the links “n1” and “n2” is reflected in the first period latest map data to create the second period latest map data (corresponding to the next period latest map data), but the links “n1”, “ The first period second auxiliary map data is made the second period second auxiliary map data (corresponding to the second period second auxiliary map data) without reflecting the deletion of “n2” in the first period second auxiliary map data.

  Here, as shown in FIG. 16, the difference group extraction processing unit 32 creates temporary second auxiliary map data by copying the second phase second auxiliary map data, and sets the links “n1” and “n2”. From the temporary “second auxiliary map data”, the node “H” (corresponding to the first node) located at both ends of the deleted links “n1” and “n2” to the node “L” (corresponding to the second node) (The route search from the node “L” to the node “H” may be performed) on the temporary second auxiliary map data, but the links “n1” and “n2” are temporarily used in the second auxiliary map data. However, since the deletion of the links “l1” and “l2” is not reflected, the route search from the node “H” to the node “L” is successful. Specifically, the route search via the links “j1”, “l1”, and “m1” succeeds.

  Then, the difference group extraction processing unit 32 determines that there is a dependency between the deletion of the links “l1” and “l2” and the deletion of the links “n1” and “n2” included in the route that has been successfully searched for a route. Then, the deletion of the links “l1” and “l2” determined to have the dependency and the deletion of the links “n1” and “n2” are grouped as map difference data and stored in the difference group database 34. Here, in the present embodiment, when road changes (updates) are grouped and stored as map difference data as described above, information on the changed road purpose (road purpose) is added.

  In the present embodiment, as described above, every time a map update (change in road, that is, change in addition, change, deletion, etc.) occurs, the change in the road is grouped as map difference data. And stored in the difference group database 34, that is, the difference group extraction process is sequentially executed.

  According to this configuration, it is possible to realize the minimum grouping that guarantees the road network. Then, by performing such a difference group extraction process, it is possible to perform the next process without mixing changes in other adjacent roads. Further, even if the change is not directly connected as a road network, it is possible to handle data having a dependency relation as a road network as one group data.

  An example of when a road is updated (changed or changed) is when the main road that is the core is generated and changed so that it can travel efficiently between the roads. Changes can also be extracted by difference grouping.

  Further, in the difference group extraction process described above, every time a map update (change of road, that is, change of road addition, change, deletion, etc.) occurs, the change of the road is grouped and stored as map difference data. Instead of this, instead of this, the updated map database (version A (latest version) map database) and the old map database before updating the map (version B (older version more than one generation before)) A portion having road changes, and the extracted road change portions may be grouped and stored as map difference data. Even with this configuration, a large number of difference groups can be extracted and stored in substantially the same manner as described above.

  Next, processing for creating or correcting a road change model by the model extraction processing unit 36 will be described with reference to FIGS. 17 to 19. First, an example of a road change model created by the model extraction processing unit 36 is shown in FIG. As shown in FIG. 17, the road change model has a model number, a road purpose, a road change pattern, a determination allowable value, and guidance information. The model NO is a number (model number) for specifying the road change model. As described above, the road purpose is information indicating the purpose of the road, such as a left or right turn on a general road, or a transfer from a freeway main line to a main line.

  The road change pattern includes a road pattern before the change and a road pattern after the change. Judgment allowances are information on the predetermined deviation width allowed for the position coordinates of the start and end points of the road pattern before the change (coordinates connected to the original road), and the start and end points of the road pattern after the change. It is composed of information of a predetermined deviation width allowed for position coordinates (coordinates connected to the original road). Guidance information includes (appropriate) car navigation guidance information necessary when the vehicle travels in the changed road pattern, such as graphic information (changed road image information), position coordinates of the guidance start point, and guidance end point. Position coordinates, guidance messages, and the like. Note that a set deviation width is allowed for the position coordinates of the guidance start and guidance end points. Further, the guidance start and guidance end points are formed based on the determination allowable value. That is, the point at which the guidance information is output can be adjusted based on the determination allowable value.

  Next, the processing operation of the model extraction processing unit 36 will be described with reference to the flowchart of FIG. First, in step S401 in FIG. 18, the model extraction processing unit 36 determines whether all the difference groups in the difference group database 34 have been processed. If all the difference groups have not been processed, the process proceeds to “NO” in step S401 and proceeds to step S402 to acquire an unprocessed difference group from within the difference group database 34.

  Subsequently, the process proceeds to step S403, and it is determined whether or not the acquired difference group is collated with all road change models (may be referred to as map model patterns) in the road change model database 37. Here, when not collating with all road change models, it progresses to "NO" in step S403, progresses to step S404, and acquires the road change model which is not collated from the road change model database 37.

  Next, the process proceeds to step S405, and it is determined whether or not the road purpose of the target difference group matches the road purpose of the road change model to be verified. If they do not match, the process proceeds to “NO” in step S405, and returns to step S403. If they match in step S405, the process proceeds to “YES”, and the process proceeds to step S406, in which whether or not the road change pattern of the target difference group matches the road change pattern of the road change model to be verified. to decide. If they do not match, the process proceeds to “NO” in step S406 and returns to step S403. If they match in step S406, the process proceeds to “YES”, and the process proceeds to step S407, in which the determination allowable value of the road change model to be verified is referred to with reference to the data of the target difference group (for example, the road determination allowable value). to correct. After this, the process returns to step S401.

  In step S403, when all the road change models in the road change model database 37 are collated, the process advances to “YES” in step S403, and then advances to step S408 to give a new road change model (a new model NO is assigned). The process of creating a road change model is started. First, it progresses to step S409 and the road objective of a new road change model is produced | generated with reference to the data (for example, road objective) of the object difference group.

  Subsequently, the process proceeds to step S410, and a road change pattern of a new road change model is generated with reference to data of the target difference group (for example, a road change pattern). Then, the process proceeds to step S411, and a road determination allowable value of a new road change model is generated with reference to data of the target difference group (for example, a road change pattern). In this case, as the determination allowable value, an initial value without a deviation width is set. Next, the process proceeds to step S412, and by referring to the data of the target difference group (for example, the purpose of the road, the change pattern, etc.), the road guidance information of the new road change model (guidance message (guidance start information, guidance end point information) And graphic information for guidance). Then, a new road change model including the generated information and a new model NO is stored in the road change model database 37. Thereafter, the process returns to step S401, and the above-described processing is repeated. When all the difference groups in the difference group database 34 are processed in step S401, the process proceeds to “YES”, and the process of the model extraction processing unit 36 is terminated.

  Here, a special example of the change pattern of the road change model will be described. The change pattern of the road change model that changes from FIG. 6A to FIG. 6B is a change from the loop type to the stack type. As such a change pattern of the change from the loop type to the stack type, there is a change pattern of the road change model that changes from FIG. 19A to FIG. 19B. If these two change patterns are determined in consideration of only the change in the road shape, ie, the change from the loop type to the stack type, they are determined to be the same, and as a result, they may be guided by the same guidance information.

  Therefore, a matching condition for distinguishing the two change patterns is required. For example, the road shape is within an acceptable range for some errors and differences in size, but it is possible to clearly distinguish the above two change patterns by strictly determining whether there is a branch in the middle of the road, etc. It becomes. Therefore, in the present embodiment, information indicating whether or not a branch has occurred on the road is included in the change pattern of the road change model (or difference group).

  According to this embodiment having such a configuration, the difference group to be collated is compared with all the road change models in the road change model database 37, and if there is no matching road change model, the difference group to be collated Since a new road change model is generated with reference to the data, necessary road change models can be sequentially created. In the present embodiment, when the road change model is generated, the road purpose, the change pattern, the determination allowable value, and the guidance information are generated and stored. And route guidance of the route (road) along the road change model can be appropriately executed. Further, in the present embodiment, the difference group to be collated is collated with all the road change models in the road change model database 37, and when they match, the determination value of the road change model is corrected. Therefore, since the accuracy of the road change model can be improved, route guidance of the route (road) along the road change model can be more appropriately executed.

(Fourth embodiment)
FIG. 20 shows a fourth embodiment of the present invention. In addition, the same step number is attached | subjected to the same step as 1st Embodiment (refer FIG. 2). In the fourth embodiment, first, in S501 of FIG. 20, the travel locus creation unit 17 calculates the current position coordinates (latitude and longitude values) detected by the position detection unit 2 at regular intervals (for example, 1 to 5 seconds). The information of the travel locus is taken in and created (similar to the processing of S101 in FIG. 2), and the created travel locus information is stored in the memory unit 5. The traveling direction can be determined from the traveling locus. Further, since the travel distance and the time required for the travel can be obtained, the average travel speed can also be known. Furthermore, in the present embodiment, for example, information on the traveling locus of about several hundred to several thousand km (or about several weeks to several months) can be stored in the memory unit 5 as past traveling locus information. It has become.
Next, the travel trajectory obtained in this way is compared with the road shape data of the road map data acquired from the map data storage unit 3 to determine whether or not the vehicle is in a road leaving state (S102). And when it is a road leaving state (S102: YES), based on the information of the past running locus memorize | stored in the memory part 5, when it assumes that it did not leave the road, it will be expected to drive originally. It is determined whether or not the road of the road map data, that is, a road that has been abolished (abandoned road, old road) has been driven in the past (S510). Here, when the abandoned road has traveled in the past (S510: YES), the past travel locus of the abandoned road is read from the memory unit 5. In this case, the abandoned road and the roads around it are read as a set.

  Subsequently, it is determined whether or not there is a road trajectory in the same road leaving state as compared with information on the road trajectory in the road leaving state accumulated as described later (S103). If there is no similar road leaving track (S103: NO), the number of creation is set to 1 (S104), and the road leaving track (that is, the new road and the roads before and after the new road) The memory unit 5 stores information including a set of information on the travel trajectory) and information on past travel trajectories read out in S520 (that is, travel trajectory traveled on the abandoned road and the roads before and after that). (S505), and this process ends. That is, information (traveling track information) such as each traveling locus is stored in the memory unit 5 as newly created roads (new roads) and abandoned roads (discontinued roads) that do not exist in the road map data. Keep it. In this case, the control unit 9 has functions as a traveling locus information collecting unit and a past traveling locus information collecting unit.

  On the other hand, if there is a similar traveling locus (S103: YES), it is determined whether or not the number of times the traveling locus is created is greater than or equal to a predetermined value (S106). : NO), the number of times of creation for the travel locus is increased by 1 (S107), and this process is terminated.

  In this way, when the traveling track of the same road leaving state is created and the number of times of creation increases, and the number of times of creation of the traveling locus exceeds a predetermined value (S106: YES), in S505. The accumulated traveling locus information, that is, information such as the traveling locus of the new road and the preceding and following roads and the traveling locus of the abolished road and the preceding and following roads is transmitted to the information center 21 (S508). Thereafter, the fact that the information such as the travel locus has been transmitted is recorded in the memory unit 5 (S509), and this process is terminated. In S509, if the fact that information such as the travel locus has been transmitted is recorded in the memory unit 5, it can be seen that the road corresponding to the transmitted travel locus has already been transmitted. When traveling on a road, it is possible to prevent the above-described processing (processing such as determining as a new road or transmitting new road information or the like to the information center 21) from being executed.

  The configuration of the fourth embodiment other than that described above is the same as that of the first embodiment. Therefore, also in the fourth embodiment, substantially the same operational effects as in the first embodiment can be obtained. In particular, according to the fourth embodiment, the information such as the new road and the traveling trajectories of the roads before and after the new road and the information such as the abandoned road and the traveling trajectories of the roads before and after the set are transmitted to the information center 21 as a set. Therefore, in the information center 21, the new information is obtained based on the received information such as the new road and the traveling trajectory of the road before and after it, the information such as the abandoned road and the traveling trajectory of the road before and after the new road, and the road change model. Since it becomes a structure which estimates a road and an abolition road, the precision of estimation of a new road and an abolition road can be improved.

  In each of the above embodiments, when the information center 21 estimates the new road and the abandoned road, the information on the travel path of the new road transmitted from the navigation device 1 of the vehicle A is stored in the database 24. Inferred by comparing existing road change models, but is not limited to this. New information is abolished in consideration of traffic information accumulated (collected) at the information center 21, such as traffic jam information and road construction information. You may comprise so that a road may be estimated. If comprised in this way, a new road and an abolition road can be estimated still more correctly compared with the structure estimated only based on the information of the travel locus of a new road, and a road change model. The information center 21 has a function of receiving traffic information from, for example, VICS (registered trademark) via the line terminal device 22, the telephone station 19, and the wireless base station 18 (function as traffic information collecting means). It is preferable to provide.

  In the second embodiment, the currently used road map data stored in the database 24 of the information center 21 and the road map data mounted in the navigation device 1 of the vehicle B are the same. As an example, the routes R1 and R2 from the current location to the destination are calculated, but the following configuration may be used instead. Usually, in each navigation device 1 of a plurality of vehicles, road map data of various versions (and various map data manufacturing companies) are used. The database 24 of the information center 21 stores road map data of various versions (and various map data manufacturing companies). Therefore, when the destination information and the current location (departure location) information of the vehicle B are transmitted from the navigation device 1 of the vehicle B to the information center 21, the identification information (that is, version information and map data manufacturing company) of the road map data is transmitted. (Information such as name) is added and transmitted. The information center 21 receives the destination information, the current location (departure location) information of the vehicle B, and the road map data identification information transmitted from the navigation device 1 of the vehicle B, and is stored in the database 24. Using the same version and the same map data manufacturer's road map data (that is, the same as the road map data mounted in the navigation device 1 of the vehicle B), as in the second embodiment, Processing for calculating routes R1 and R2 from the current location to the destination, road shape data stored in the calculated routes R1 and R2 and road map data, intersection location information, level crossing location information, etc. Therefore, it is preferable to perform a process of calculating points necessary for the guidance instruction and calculating what kind of guidance instruction is necessary.

  Furthermore, an algorithm (processing program) for route calculation processing (and route guidance calculation processing) performed by the vehicle navigation device 1 and an algorithm (processing program) for route calculation processing (and route guidance calculation processing) performed by the information center 21 are provided. In order to make the same, the program identification information for identifying the algorithm (processing program) of the route calculation processing (and route guidance calculation processing) of the vehicle navigation device 1 is the destination information and the current location information (departure location) information of the vehicle. And the identification information of the road map data may be transmitted to the information center 21 together. If comprised in this way, even if the algorithm (processing program) of the vehicle navigation apparatus 1 is various, in the navigation apparatus 1 of the vehicle and the information center 21, a route calculation process (and the same algorithm (processing program)) Route guidance calculation processing) can be performed.

  In the first embodiment, the information center 21 uses old road map data (hereinafter referred to as old road map data) used in the past and the latest updated road map data (hereinafter referred to as new road map data). Compared with the second road map data), a large number of road change parts with abolished roads and new roads currently in use are extracted, and a road change model based on the abolished roads and new roads Are created and stored in the database 24. However, the present invention is not limited to this. For example, the latest road map data is downloaded by the navigation device 1, the information is stored, the old road map data used before the download is compared with the new road map data after the download, and abolished. A large number of road change portions where there is a road that has been used and a new road that is currently in use are extracted, and many types of road change models are created based on the abolished road and the new road, and these are stored in the navigation device 1 It may be.

  In addition, it is not necessary for the information center 21 or the navigation device 1 to create a road change model by comparing the old road map data with the new road map data, and a large number of road change models are stored in advance in the information center 21 or the navigation device 1. The abandoned road and the new road may be estimated based on the information on the travel locus of the new road and the road change model stored in the navigation device 1 provided in advance. At this time, it is preferable to update the road map data stored in the navigation device 1.

  In the third embodiment, the model creation device 31 is provided in the information center 21. However, the present invention is not limited to this, and the model creation device is provided in an in-vehicle navigation device or other dedicated terminal. You may comprise.

  In each of the above-described embodiments, the in-vehicle navigation device 1 has been described as an example of the navigation device. However, the present invention is not limited to this, and for example, a PND (Portable Navigation Device) or a portable navigation device may be used. Moreover, although the vehicle was demonstrated, it is not limited to this, You may apply to it, if it moves on a road.

  In the drawings, 1 is an in-vehicle navigation device (navigation device), 2 is a position detection unit, 3 is a map data storage unit (storage means), 4 is a switch information input unit, 5 is a memory unit, 8 is a data communication unit, 9 Is a control unit (running locus information collecting means, past running locus information collecting means), 10 is a map data acquisition unit, 11 is a map matching unit, 12 is a route calculation unit, 13 is a route guide unit, 16 is a communication control unit, 17 Is a travel locus creation unit (travel locus detection means), 18 is a radio base station, 19 is a telephone station, 21 is an information center, 22 is a line terminal device, 23 is a server, 24 is a database, 25 is old road map data, 26 Is a new road map data, 31 is a model creation device, 32 is a difference group extraction processing unit, 33 is a map database group, 34 is a difference group database, 35 is a map update information input unit, 36 Model extraction processor 37 road change model database, 38 the latest map database 39 the first auxiliary map database, 40 denotes a second auxiliary map database.

Claims (4)

A navigation device comprising storage means for storing the first road map data, travel locus detection means for detecting the travel locus of the moving body, and communication means for transmitting information to the outside;
A road information update system comprising: an information center that stores second road map data and includes a communication unit that communicates information to the navigation device;
The information center includes the first road map data, receives the destination information and the departure point information transmitted from the navigation device, and uses the first road map data to receive the current location. A process for calculating the route R1 from the destination to the destination, and a process for calculating the guidance information of the calculated route R1,
Performing a process of calculating a route R2 from the current location to the destination using the second road map data, and a process of calculating guidance information of the calculated route R2,
The guide information on the route R1 is compared with the guide information on the route R2, and the guide information cancel information for canceling the guide information that exists on the route R1 and does not exist on the route R2, and the guide information that does not exist on the route R1. And is configured to transmit guide information additional information for adding guide information existing in the route R2 to the navigation device,
The navigation device executes a process of calculating a route R1 from the current location to the destination using the first road map data, and a process of calculating guidance information of the calculated route R1, and the information center The guide information cancel information and the guide information additional information from the route R1 are received based on the received guide information cancel information and the guide information additional information. It consists added of to reflect,
The road information update system, wherein the guidance information cancellation information includes information for preventing an old map and an abandoned road from being displayed when a map or a route is displayed on the navigation device . A traveling locus detection means for detecting a traveling locus of the moving body, a storage means for storing first road map data, and a communication means for transmitting information to the outside are mounted on a moving body traveling on a road. In navigation devices,
It is configured to transmit the information on the starting point of the mobile body and the information on the destination to the information center,
A process for calculating a route R1 from a departure place to a destination using the first road map data, and a process for calculating guide information for the calculated route R1, and further,
The guidance information cancellation information for canceling the guidance instruction message on the route R1 transmitted from the information center and the guidance information additional information for adding the guidance instruction message are received, and the received guidance information cancellation information and guidance information addition are received. Based on the information, it is configured to reflect the cancellation of the guidance information and the addition of the guidance information to the guidance information of the route R1 ,
The navigation apparatus, wherein the guidance information cancellation information includes information for preventing an old map and an abandoned road from being displayed when a map or a route is displayed on the navigation apparatus. The information center includes the first road map data stored in the navigation device, and second road map data different from the first road map data.
Processing for receiving the information on the departure place and the destination information of the mobile body transmitted from the navigation device, and calculating a route R1 from the current location to the destination using the first road map data; A process for calculating the calculated route R1 guidance information;
Further, a process of calculating a route R2 from the current location of the mobile body to the destination using the second road map data and a process of calculating guidance information of the calculated route R2 are executed.
Compare the guidance information of the route R1 and the guidance information of the route R2, and cancel the guidance information that exists in the route R1 but does not exist in the route R2, and does not exist in the route R1. The navigation apparatus according to claim 2, wherein the navigation apparatus transmits guidance information additional information that is guidance information and adds the guidance information existing on the route R2 to the navigation apparatus.   4. The navigation apparatus according to claim 2, wherein the guidance information is at least one of road map data or guidance instructions.

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